TY - JOUR
T1 - Surface and subsurface hydrology of debris-covered Khumbu Glacier, Nepal, revealed by dye tracing
AU - Miles, Katharine
AU - Hubbard, Bryn
AU - Quincey, Duncan Joseph
AU - Miles, Evan S.
AU - Irvine-Fynn, Tristram
AU - Rowan, Ann Victoria
N1 - Funding Information:
KM is funded by an AberDoc PhD Scholarship (Aberystwyth University) and was supported for this fieldwork by the Mount Everest Foundation and Postgraduate Research Awards from the British Society for Geomorphology, the Royal Geographical Society (with IBG) and Aberystwyth University Department of Geography and Earth Sciences. The fieldwork was also supported by a HEFCW Capital Equipment Grant awarded to Aberystwyth University, and the ‘EverDrill’ Natural Environment Research Council Grant awarded to Aberystwyth University (NE/P002021) and the Universities of Leeds and Sheffield (NE/P00265X). We are grateful to Himalayan Research Expeditions, particularly Mahesh Magar, for invaluable help during the field season, to Martin Kirkbride for encouraging conversations in the field, and to Doug Benn for sharing and discussing observations of the Khumbu drainage system. We are grateful to the Sagarmatha National Park Authority for providing the necessary research permits.
Funding Information:
KM is funded by an AberDoc PhD Scholarship ( Aberystwyth University ) and was supported for this fieldwork by the Mount Everest Foundation and Postgraduate Research Awards from the British Society for Geomorphology , the Royal Geographical Society (with IBG) and Aberystwyth University Department of Geography and Earth Sciences . The fieldwork was also supported by a HEFCW Capital Equipment Grant awarded to Aberystwyth University, and the ‘EverDrill’ Natural Environment Research Council Grant awarded to Aberystwyth University ( NE/P002021 ) and the Universities of Leeds and Sheffield ( NE/P00265X ). We are grateful to Himalayan Research Expeditions, particularly Mahesh Magar, for invaluable help during the field season, to Martin Kirkbride for encouraging conversations in the field, and to Doug Benn for sharing and discussing observations of the Khumbu drainage system. We are grateful to the Sagarmatha National Park Authority for providing the necessary research permits.
Publisher Copyright:
© 2019 The Author(s)
PY - 2019/5/1
Y1 - 2019/5/1
N2 - While the supraglacial hydrology of debris-covered glaciers is relatively well studied, almost nothing is known about how water is transported beneath the glacier surface. Here, we report the results of sixteen fluorescent dye tracing experiments conducted in April–May 2018 over the lowermost 7 km of the high-elevation, debris-covered Khumbu Glacier, Nepal, to characterise the glacier's surface and subsurface drainage system. Dye breakthroughs indicated a likely highly sinuous and channelised subsurface hydrological system draining water from the upper part of the ablation area. This flowpath was distinct from the linked chain of supraglacial ponds present along much of the glacier's lower ablation area, through which water flow was extremely slow (∼0.003 m s
−1 ), likely reflecting the study's timing during the pre-monsoon period. Subsurface drainage pathways emerged at the glacier surface close to the terminus, and flowed into small near-surface englacial reservoirs that typically delayed meltwater transit by several hours. We observed rapid pathway changes resulting from surface collapse, indicating a further distinctive aspect of the drainage of debris-covered glaciers. We conclude that the surface and subsurface drainage of Khumbu Glacier is both distinctive and dynamic, and argue that further investigation is needed to refine the characterisation and test its regional applicability to better understand future Himalayan debris-covered glacier meltwater delivery to downstream areas.
AB - While the supraglacial hydrology of debris-covered glaciers is relatively well studied, almost nothing is known about how water is transported beneath the glacier surface. Here, we report the results of sixteen fluorescent dye tracing experiments conducted in April–May 2018 over the lowermost 7 km of the high-elevation, debris-covered Khumbu Glacier, Nepal, to characterise the glacier's surface and subsurface drainage system. Dye breakthroughs indicated a likely highly sinuous and channelised subsurface hydrological system draining water from the upper part of the ablation area. This flowpath was distinct from the linked chain of supraglacial ponds present along much of the glacier's lower ablation area, through which water flow was extremely slow (∼0.003 m s
−1 ), likely reflecting the study's timing during the pre-monsoon period. Subsurface drainage pathways emerged at the glacier surface close to the terminus, and flowed into small near-surface englacial reservoirs that typically delayed meltwater transit by several hours. We observed rapid pathway changes resulting from surface collapse, indicating a further distinctive aspect of the drainage of debris-covered glaciers. We conclude that the surface and subsurface drainage of Khumbu Glacier is both distinctive and dynamic, and argue that further investigation is needed to refine the characterisation and test its regional applicability to better understand future Himalayan debris-covered glacier meltwater delivery to downstream areas.
KW - Glacier hydrology
KW - dye tracing
KW - debris-covered glacier
KW - Himalaya
KW - subglacial
KW - glacier hydrology
UR - http://www.scopus.com/inward/record.url?scp=85062385428&partnerID=8YFLogxK
U2 - 10.1016/j.epsl.2019.02.020
DO - 10.1016/j.epsl.2019.02.020
M3 - Article
SN - 0012-821X
VL - 513
SP - 176
EP - 186
JO - Earth and Planetary Science Letters
JF - Earth and Planetary Science Letters
ER -